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This section describes

the best possible performance and scale for a given virtual machine resource profile

.

Purpose

Real-time applications have stringent requirements with respect to jitter, latency, quality of service and packet loss. The migration of real-time applications to an all-software environment requires deterministic response to failures and performance in the scheduler of the hypervisor and the host

operating system (OS).

Some fine-tuning can be done to achieve maximum scale and reliable performance for the SBC SWe and ancillary applications. This

page defines

the areas that

can be fine-tuned in OpenStack/KVM

environments.

The

Ribbon SBC SWe requires a reservation of CPU, memory and hard disk resources in virtual machines in addition to implementing certain performance tuning parameters for any production deployments that

support over 100 concurrent sessions.

Recommended BIOS Settings

Ribbon recommends applying the BIOS settings in the table below to all Nova compute hosts running the

Ribbon VMs for optimum performance:

• S-SBC
• M-SBC
• T-SBC
• I-SBC

CPU Pinning Overview

Apply below settings to all Nova compute hosts in the pinned host aggregate.

From the hypervisor's perspective, a virtual machine appears as a single process that should be scheduled on the available CPUs. By design, hypervisors

schedule the clock cycle on a different processor. While this is certainly acceptable in environments where the hypervisor is allowed to over-commit, this contradicts the requirements for real-time applications. Hence,

Ribbon requires CPU pinning to prevent applications from sharing a core.

By default, virtual CPUs are not assigned to a host CPU, but

Ribbon requires CPU pinning to maintain the requirements of real-time media traffic. The primary reason for pinning

is to prevent other workloads (including those of the host OS) from causing significant jitter in media processing. It is also possible to introduce significant message queuing delays and buffer overflows at higher call rates.

Instances with pinned CPUs

cannot use the CPUs of another pinned instance. This prevents resource contention and improves processor cache efficiency by reserving physical cores. Host

aggregate filters or

availability zones can be used to select compute hosts for pinned and non-pinned instances. OpenStack clearly states that pinned instances must be separated from unpinned instances

as the latter will not respect the resourcing requirements of the former.

To enable CPU pinning, execute the following steps on every compute host

:

1. To retrieve the NUMA topology for the node, execute the below command:

   Code Block
   # lscpu | grep NUMA NUMA node(s): 2 NUMA node0 CPU(s): 0-11,24-35 NUMA node1 CPU(s): 12-23,36-47

1. Tip
   title Tip
   In this case, there are two Intel

1. sockets with 12 cores each; configured for hyper-threading. CPUs are paired on physical cores in the pattern 0/24, 1/25, etc. (The pairs are also known as thread siblings).

1. The following code

1. must be added at the end of /etc/default/grub

1. :

   Code Block
   GRUB_CMDLINE_LINUX="$GRUB_CMDLINE_LINUX hugepagesz=1G hugepages=256"

   Tip
   title

1. Tip

   The number

1. of hugepages depends on how many VM instances

1. are created on this host and multiplied by the memory size of each instance. The hugepagesz value should be the maximum hugespace value supported by the kernel being used.

2. A pin set limits KVM to placing guests on a subset of the physical cores and thread siblings. Omitting some cores from the pin set ensures that there are dedicated cores for the OpenStack processes and application. The pin set

1. ensures that KVM guests never use more than one thread/core while leaving the additional thread for shared KVM/OpenStack processes. This mechanism

1. boosts the performance of non-threaded guest applications by allowing the host OS to schedule closely related host OS processes on the same core with the guest OS (e.g. virtio processes). The following example built on the CPU and NUMA topology shown in

1. step 1 (above):
   
   

   • For

1. • a hyper-threading host: Add the CPU pin set list to vcpu_pin_set in the default section of /etc/nova/nova.conf:

     Code Block
     vcpu_pin_set=2-11,14-23,26-35,38-47

1. •  For compute nodes, servicing VMs which can be run on

1. • hyper-

1. • threaded hosts, the CPU

1. • pin set includes all thread siblings except for the cores which are carved out and dedicated to the host OS. The resulting CPU

1. • pin in the example dedicates cores/threads 0/24,1/25 and 12/36,13/37 to the host OS. VMs

1. • use cores/threads 2/26-11/35 on NUMA node 0, and cores/threads 14/38-23/47 on NUMA node 1.

2. Update the boot record and reboot the compute node.

3. Configure the Nova

1. scheduler to use NUMA

1. topology and aggregate instance extra specs on Nova controller hosts:

On each node where the OpenStack

compute scheduler (openstack-nova-scheduler) runs, edit the nova.conf file that is located at /etc/nova/nova.conf. Add the AggregateInstanceExtraSpecFilter and

NUMATopologyFilter values to the list of scheduler_default_filters. These filters are used to segregate the compute nodes that can be used for CPU pinning from those that cannot and to apply NUMA-aware scheduling rules when launching instances:

• • scheduler_default_filters=RetryFilter,AvailabilityZoneFilter,RamFilter,

  • ComputeFilter,ComputeCapabilitiesFilter,ImagePropertiesFilter,CoreFilter,

  • PciPassthroughFilter,NUMATopologyFilter,AggregateInstanceExtraSpecsFilter
    
    In addition to support SR-IOV, enable the PciPassthroughFilter and restart the openstack-nova-

• • scheduler service.

    Code Block
    systemctl restart openstack-nova-scheduler.service

    With CPU pinning

• • enabled,

• •  Nova must be configured to use it. See the section below for a method to use a combination of host-aggregate

• • and Nova flavor keys.

Anchor
model model

CPU Model Setting

Apply

the following settings to

all Nova compute hosts where

The CPU model defines the CPU flags and

CPU architecture that

are exposed from the host processor to the guest.

Non-S/M/T/I-SBC Instances

Ribbon supports either host-passthrough or host-model for non-S/M/T-SBC instances

.

S/M/T/I-SBC Instances

Modify the nova.conf file located at /etc/nova/nova.conf.

Ribbon recommends setting the CPU

mode to host-

model for SBC instances

.

This setting is defined in /etc/nova/nova.conf:

This change is

made in /etc/nova/nova-compute.conf:

CPU Frequency Setting in the Compute Host

Check the current configuration of the CPU frequency setting using the following command on the host system.

# cat /sys/devices/system/cpu/cpu*/cpufreq/scaling_governor

The CPU frequency setting must be set to performance to improve VNF performance. Use the following command on the host system:

# echo "performance" | tee /sys/devices/system/cpu/cpu*/cpufreq/scaling_governor

Removal of CPU and Memory Over Commit

Apply the following settings to all Nova compute hosts where Ribbon VMs are installed:

• S-SBC
• M-SBC
• T-SBC
• I-SBC

The default settings for CPU (1.16) and Memory (1:5). Modify the nova.conf file located at /etc/nova/nova.conf, and change the default settings of cpu_allocation_ratio and ram_allocation_ratio to (1:1) for resource reservation.

cpu_allocation_ratio = 1.0
ram_allocation_ratio = 1.0

Adjusting the Tx Queue Length of a Tap Device

Apply the following settings to all Nova compute hosts where Ribbon VMs are installed:

• S-SBC
• M-SBC
• T-SBC
• I-SBC

While using 1:1 HA mode with virtual nics (virtio), OpenStack creates tap devices for each port on the guest VM. The Tx queue length of the tap devices is set to 500 by default which defines the queue between the OVS and the VM instance. The value 500 is too low on the queue; this increases the possibility of packet drops at the tap device. Set the Tx queue length to a higher value that increases performance and reliability. Use a value that matches your performance requirements. 

The sample commands below are for Ubuntu 4.4; use the syntax that corresponds to your operating system.

Modify the 60-tap.rules file and add the KERNEL command
# vim /etc/udev/rules.d/60-tap.rules
KERNEL=="tap*", RUN+="/sbin/

ip link set %k txqueuelen 1000" - Add this line
# udevadm control --reload-rules
Use the below command to apply the rules to already created interfaces:
# udevadm trigger --attr-match=subsystem=net

Kernel Same-page Metering (KSM) Settings

Apply

the following settings to

all Nova compute hosts where

Ribbon VMs are installed:

• S-SBC
• M-SBC
• T-SBC
• I-SBC

Kernel same-page metering (KSM) is a technology

that finds common memory pages inside a Linux system and merges the pages to save memory resources. In the event

that one of the copies

is updated, a new copy is created so the function is transparent to the processes on the system. For hypervisors, KSM is highly beneficial

when multiple guests are running with the same level of the operating system. However, there is an overhead due to the scanning process which may cause the applications to run slower

. The SBC SWe requires that KSM

be turned

off.

The sample commands below are for Ubuntu 4.4

; use the syntax that corresponds to your operating system.

# echo 0 >/sys/kernel/mm/ksm/run
# echo "KSM_ENABLED=0" > /etc/default/qemu-kvm

Once

KSM

turned-off, it is important to verify that there is still sufficient memory on the hypervisor. When the pages are not merged, it may increase memory usage and lead to swapping that negatively impacts performance

.

Hyper-

threading Support

Hyper-threading is designed to use

idle resources

on Intel processors. A physical core is split into

two logical cores

creating parallel threads. Each logical core has its own architectural state.

The actual performance gains

from using hyper-threading

depend on the amount of idle resources on the physical CPU.

Hyper-threading

is shown in the diagram below.

Ribbon VNF CPU Pinning and Hyper-threading Support

Hyper-threading should be enabled in the BIOS for all Ribbon VNF elements.

Ribbon

VNF Tested Configurations

the Nova compute scheduler.

Host-Aggregate Method for SMP VM Placement

A few methods exist to influence VM placement in OpenStack environments. The method described in this section

segregates Nova compute nodes into discrete host aggregates and use Nova flavor-key aggregate_instance_extra_specs so that specific flavors will use specific host aggregates. For this to work, all flavors must specify a host aggregate. This is accomplished by first assigning all existing flavors to a "normal" host aggregate, then assigning only the Nova compute hosts configured for non-

hyper-

threading to a "Pin-Isolate" host aggregate.

From the Openstack CLI, create the host aggregates and assign compute hosts:

% nova aggregate-create Active-Pin-Isolate
% nova aggregate-set-metadata Active-Pin-Isolate Active-Pin-Isolate=true
% nova aggregate-add-host Active-Pin-Isolate {first nova compute host in aggregate}
    {repeat for each compute host to be added to this aggregate}

% nova aggregate-create Active
% nova aggregate-set-metadata Active Active=true
% nova aggregate-add-host Active {first nova compute host in aggregate}
    {repeat for each compute host to be added to this aggregate}

From

the

Openstack

CLI,

assign

all

existing

flavors

to

the

non-pinned

host

aggregate:

Example Flavor Definitions

The flavor definitions

listed below

include the following

extra specs:

• hw:cpu_policy=dedicated: This setting enables CPU pinning.
  
  
• hw:cpu_thread_policy=

• prefer: This setting allocates each vCPU on thread siblings of physical CPUs.
  
  
• hw:numa_nodes: This setting defines how the host processor cores are spread over the host NUMA nodes.

• When this is set to 1, it ensures that the cores are not spread over more than 1 NUMA node, ensuring the performance of having one; otherwise Nova would be free to split the cores up between available NUMA nodes.
  
  

• hw:cpu_max_sockets: This setting defines how KVM exposes the sockets and cores to the guest. Without this setting, KVM always exposes a socket for every core

• with each socket having one core. This requires a mapping in the host virtualization layer to convert the topology, resulting in a measurable performance degradation. That performance overhead can be avoided by accurately matching the advertised cpu_sockets to the requested host numa_nodes. Using the *_max_* variable ensures that the value cannot be overridden in the image metadata supplied by tenant-level users.

SBC SWe Flavor Example

To create an M-SBC SWe flavor with 20 vCPUs, 32 GiB of RAM and 100 GB of Hard disk, enter the following Nova commands from the Openstack CLI.

% nova flavor-create 

% nova flavor-key MSBC set hw:numa_nodes=1

To create an S-SBC SWe flavor with 128 GiB RAM and 100 GB of Hard Disk based on 2 x NUMA nodes of 20 vCPUs each (For example, 40 vCPUs for S-SBC), enter the following Nova commands from the Openstack CLI.

% nova flavor-create 

2

Regarding the default setting, numa_mempolicy=preferred, the NUMA memory allocation policy is set to "strict" which forces the kernel to allocate memory only from the local NUMA node where processes are scheduled. If memory on one of the NUMA node is exhausted for any reason, the kernel cannot allocate memory from another NUMA node even when memory is available on that node. With this in mind, using the default setting would have a negative impact on applications like the S-SBC. This setting is in reference to the link below:

https://specs.openstack.org/openstack/nova-specs/specs/juno/implemented/virt-driver-numa-placement.html

References

• CPU Pinning and NUMA Topology

• : http://redhatstackblog.redhat.com/2015/05/05/cpu-pinning-and-numa-topology-awareness-in-openstack-compute/

• OpenStack Flavor

• Information:

•  https://docs.openstack.org

• /nova/queens/user/flavors.html

• OpenStack CPU

• Topologies Information: https://docs.openstack.org/nova/queens/admin

• /

• cpu-topologies.html